1 / 41

Chapter 2 Mathematical Description of Systems

Chapter 2 Mathematical Description of Systems To introduce some important concepts of systems, and then develop their associated mathematical descriptions. Outline. Some important concept of systems Linear systems Linear time-invariant systems Linearization Examples

violetta-michel
Télécharger la présentation

Chapter 2 Mathematical Description of Systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 2 Mathematical Description of Systems • To introduce some important concepts of systems, and then develop their associated mathematical descriptions. 長庚大學電機系

  2. Outline • Some important concept of systems • Linear systems • Linear time-invariant systems • Linearization • Examples • Discrete-time systems 長庚大學電機系

  3. System • A system is generally described in the Figure below: where we assume that an input results in a unique output. • SISO, MIMO, SIMO, Continuous-time system, discrete-time system. 長庚大學電機系

  4. Memoryless system:output y(t)at depends only on the input applied at (independent of past and future input) • Causal or non-anticipatory system: current output depends on past and current input but not on future input. • The state of a system at time is the information at t0 that, together with the input for determines uniquely the output for all • If the state at is known, the output is completely determined by and the input after . This implies that the state summarizes the effect of past input on future output. 長庚大學電機系

  5. A system is said to belumpedif its number of state variable is finite. Otherwise it is called adistributed system. Example: Consider the spring system If we know and the input u(t) for Then output is uniquely determined. The state at is Lumped system 長庚大學電機系

  6. Example:Consider the unit-time delay system We need the information to determine Initial state(state at ) is , which has infinite many point distributed system. 長庚大學電機系

  7. A system is said to be linear if • This is called thesuperposition property 長庚大學電機系

  8. is calledzero input response is calledzero state response (superposition principle) Output due to= output due to + output due to i.e.,response = zero-input response + zero-state response 長庚大學電機系

  9. Input-Output Description of linear system Define : Then 長庚大學電機系

  10. Consider the input-output pairs • is calledimpulseresponsewhich denotes the output observed at time t due to impulse input applied at time . 長庚大學電機系

  11. Causal for t< • A system is calledrelaxedat if x( )=0 • A linear system that is causal and relaxed at can be described by causal Linear relaxed at 長庚大學電機系

  12. MIMO System • A p input and q output linear system that is also causal and relaxed at can be described by where is calledimpulse response. • is the impulse response at time t at the ith output terminal due to an impulse applied at time at the jth input terminal. 長庚大學電機系

  13. State-space Description Every linear lumped system can be described by Implementation by Op-Amp circuits in pp. 16-17 長庚大學電機系

  14. Linear Time-invariant Systems • A system is said to be time-invariant if Otherwise, the system is time-varying • Most of system are time-varying, why study LTI system? 長庚大學電機系

  15. Example: Two time-varying examples: • In state space representation, how to determine a system is linear? time invariant? 長庚大學電機系

  16. Input-output Description • Time invariant linear, time-invariant, causal and relax at t=0 can be described as convolution integral • output at time t due to an impulse input applied at time 0. 長庚大學電機系

  17. Unit delay Example: Consider the unit delay system • The system is Linear, time-invariant and causal, but not lumped 長庚大學電機系

  18. Example:Consider the unity feedback system • If • Let r(t) be any input with 長庚大學電機系

  19. Transfer-function matrix • is called the Laplace transform of y(t) • Forlinear, causal, relax at t=0 and time-invariant system, we have • causal 長庚大學電機系

  20. is called the transfer function of the system 長庚大學電機系

  21. ForMIMO system where is the transfer function from the jth input to the ith output. • is called transfer-function matrix or transfer matrix. 長庚大學電機系

  22. For unit-delay system, • For unity-feedback system, 長庚大學電機系

  23. Rational Transfer Function • For linear lumped system, is a rational function. We define that isproper is strictly proper isbiproper isimproper 長庚大學電機系

  24. Improper rational transfer function will amplify high-frequency noise rarely arise in practice • is called - a pole of - a zero of • D(s) and N(s) are calledcoprime if they have no common factor. 長庚大學電機系

  25. State-Space Equation • Every linear, time-invariant, lumped system can be described by • If 長庚大學電機系

  26. Linearization (Taylor’s Series Expansion) • If is differentiable at , then for small, where is the Jacobian matrix. • Let =f(x), is the 1st order (or linear) approximation of y=f(x) at 長庚大學電機系

  27. Example: consider the pendulum equation. - by letting with - The Jacobian matrix is - If - If 長庚大學電機系

  28. Examples • Consider the mechanical system. Suppose that - input u is the external force - output y is the displacement from the equilibrium - friction ~ - spring force = Then the input-output description has the form 長庚大學電機系

  29. - Transfer function (assume that y(0)=0) - Let the state-space equation is 長庚大學電機系

  30. Consider - Input-output description - Transfer matrix • where 長庚大學電機系

  31. State-space description: Let 長庚大學電機系

  32. Consider the RLC network - Apply KCL and KVL we have the state space description 長庚大學電機系

  33. Discrete-Time System • Suppose that the input and output have the same sampling period • If superposition property holds linear system response=zero-state response + zero-input response 長庚大學電機系

  34. A discrete-time system is causal if current output depends on current and past input. • is the state of the system at time . The entries of x are called state variables. • Lumped system: number of state variables is finite. Otherwise it is called a distributed system. 長庚大學電機系

  35. Input-output Description • Define : impulse sequence • Consider the input-output pairs • is called the impulse response sequencewhich is the output at time instance k excited by impulse sequence at time instance m. 長庚大學電機系

  36. Linear, causal and relaxed at k0 causal linearrelaxed at • Linear, causal, relaxed at and time-invariant discrete-convolution 長庚大學電機系

  37. Discrete Transfer Function • is called the z-transformof • For a linear, causal, relaxed at 0 and time-invariantsystem • is called discrete transfer function 長庚大學電機系

  38. Examples • Consider the unit sampling-time delay system Then • Consider the discrete-time feedback system. Then 長庚大學電機系

  39. State-space Equation • Every linear, lumped and time-invariant discrete-time system can be described as • If • Discrete transfer matrix 長庚大學電機系

  40. Example:(A money market account) • Interest rate r depends on the amount of money in the account nonlinear system. • r is constant linear system. • r is changing with time time-varying system. Otherwise it is a time-invariant system. • Consider LTI case with r=0.015% per day and compound daily. Then • If 長庚大學電機系

  41. To develop state-equation, define • Why not choose ? 長庚大學電機系

More Related